@c -*-coding: utf-8-*-
@c This is part of the GNU Emacs Lisp Reference Manual.
@c Copyright (C) 1990-1994, 2001-2017 Free Software Foundation, Inc.
@c See the file elisp.texi for copying conditions.

@node Introduction
@chapter Introduction

  Most of the GNU Emacs text editor is written in the programming
language called Emacs Lisp.  You can write new code in Emacs Lisp and
install it as an extension to the editor.  However, Emacs Lisp is more
than a mere extension language; it is a full computer programming
language in its own right.  You can use it as you would any other
programming language.

  Because Emacs Lisp is designed for use in an editor, it has special
features for scanning and parsing text as well as features for handling
files, buffers, displays, subprocesses, and so on.  Emacs Lisp is
closely integrated with the editing facilities; thus, editing commands
are functions that can also conveniently be called from Lisp programs,
and parameters for customization are ordinary Lisp variables.

  This manual attempts to be a full description of Emacs Lisp.  For a
beginner's introduction to Emacs Lisp, see @cite{An Introduction to
Emacs Lisp Programming}, by Bob Chassell, also published by the Free
Software Foundation.  This manual presumes considerable familiarity with
the use of Emacs for editing; see @cite{The GNU Emacs Manual} for this
basic information.

  Generally speaking, the earlier chapters describe features of Emacs
Lisp that have counterparts in many programming languages, and later
chapters describe features that are peculiar to Emacs Lisp or relate
specifically to editing.

  This is
@iftex
edition @value{VERSION} of
@end iftex
the @cite{GNU Emacs Lisp Reference Manual},
corresponding to Emacs version @value{EMACSVER}.

@menu
* Caveats::             Flaws and a request for help.
* Lisp History::        Emacs Lisp is descended from Maclisp.
* Conventions::         How the manual is formatted.
* Version Info::        Which Emacs version is running?
* Acknowledgments::     The authors, editors, and sponsors of this manual.
@end menu

@node Caveats
@section Caveats
@cindex bugs in this manual

  This manual has gone through numerous drafts.  It is nearly complete
but not flawless.  There are a few topics that are not covered, either
because we consider them secondary (such as most of the individual
modes) or because they are yet to be written.  Because we are not able
to deal with them completely, we have left out several parts
intentionally.

  The manual should be fully correct in what it does cover, and it is
therefore open to criticism on anything it says---from specific examples
and descriptive text, to the ordering of chapters and sections.  If
something is confusing, or you find that you have to look at the sources
or experiment to learn something not covered in the manual, then perhaps
the manual should be fixed.  Please let us know.

@iftex
  As you use this manual, we ask that you mark pages with corrections so
you can later look them up and send them to us.  If you think of a simple,
real-life example for a function or group of functions, please make an
effort to write it up and send it in.  Please reference any comments to
the chapter name, section name, and function name, as appropriate, since
page numbers and chapter and section numbers will change and we may have
trouble finding the text you are talking about.  Also state the version
of the edition you are criticizing.
@end iftex
@ifnottex

As you use this manual, we ask that you send corrections as soon as you
find them.  If you think of a simple, real life example for a function
or group of functions, please make an effort to write it up and send it
in.  Please reference any comments to the node name and function or
variable name, as appropriate.  Also state the number of the edition
you are criticizing.
@end ifnottex

@cindex bugs
@cindex suggestions
Please send comments and corrections using @kbd{M-x report-emacs-bug}.

@node Lisp History
@section Lisp History
@cindex Lisp history

  Lisp (LISt Processing language) was first developed in the late 1950s
at the Massachusetts Institute of Technology for research in artificial
intelligence.  The great power of the Lisp language makes it ideal
for other purposes as well, such as writing editing commands.

@cindex Maclisp
@cindex Common Lisp
  Dozens of Lisp implementations have been built over the years, each
with its own idiosyncrasies.  Many of them were inspired by Maclisp,
which was written in the 1960s at MIT's Project MAC@.  Eventually the
implementers of the descendants of Maclisp came together and developed a
standard for Lisp systems, called Common Lisp.  In the meantime, Gerry
Sussman and Guy Steele at MIT developed a simplified but very powerful
dialect of Lisp, called Scheme.

  GNU Emacs Lisp is largely inspired by Maclisp, and a little by Common
Lisp.  If you know Common Lisp, you will notice many similarities.
However, many features of Common Lisp have been omitted or
simplified in order to reduce the memory requirements of GNU Emacs.
Sometimes the simplifications are so drastic that a Common Lisp user
might be very confused.  We will occasionally point out how GNU Emacs
Lisp differs from Common Lisp.  If you don't know Common Lisp, don't
worry about it; this manual is self-contained.

@pindex cl
  A certain amount of Common Lisp emulation is available via the
@file{cl-lib} library.  @xref{Top,, Overview, cl, Common Lisp Extensions}.

  Emacs Lisp is not at all influenced by Scheme; but the GNU project has
an implementation of Scheme, called Guile.  We use it in all new GNU
software that calls for extensibility.

@node Conventions
@section Conventions

This section explains the notational conventions that are used in this
manual.  You may want to skip this section and refer back to it later.

@menu
* Some Terms::               Explanation of terms we use in this manual.
* nil and t::                How the symbols @code{nil} and @code{t} are used.
* Evaluation Notation::      The format we use for examples of evaluation.
* Printing Notation::        The format we use when examples print text.
* Error Messages::           The format we use for examples of errors.
* Buffer Text Notation::     The format we use for buffer contents in examples.
* Format of Descriptions::   Notation for describing functions, variables, etc.
@end menu

@node Some Terms
@subsection Some Terms

  Throughout this manual, the phrases ``the Lisp reader'' and ``the Lisp
printer'' refer to those routines in Lisp that convert textual
representations of Lisp objects into actual Lisp objects, and vice
versa.  @xref{Printed Representation}, for more details.  You, the
person reading this manual, are thought of as the programmer and are
addressed as ``you''.  The user is the person who uses Lisp
programs, including those you write.

@cindex typographic conventions
  Examples of Lisp code are formatted like this: @code{(list 1 2 3)}.
Names that represent metasyntactic variables, or arguments to a function
being described, are formatted like this: @var{first-number}.

@node nil and t
@subsection @code{nil} and @code{t}
@cindex truth value
@cindex boolean

@cindex @code{nil}
@cindex false
  In Emacs Lisp, the symbol @code{nil} has three separate meanings: it
is a symbol with the name @samp{nil}; it is the logical truth value
@var{false}; and it is the empty list---the list of zero elements.
When used as a variable, @code{nil} always has the value @code{nil}.

  As far as the Lisp reader is concerned, @samp{()} and @samp{nil} are
identical: they stand for the same object, the symbol @code{nil}.  The
different ways of writing the symbol are intended entirely for human
readers.  After the Lisp reader has read either @samp{()} or @samp{nil},
there is no way to determine which representation was actually written
by the programmer.

  In this manual, we write @code{()} when we wish to emphasize that it
means the empty list, and we write @code{nil} when we wish to emphasize
that it means the truth value @var{false}.  That is a good convention to use
in Lisp programs also.

@example
(cons 'foo ())                ; @r{Emphasize the empty list}
(setq foo-flag nil)           ; @r{Emphasize the truth value @var{false}}
@end example

@cindex @code{t}
@cindex true
  In contexts where a truth value is expected, any non-@code{nil} value
is considered to be @var{true}.  However, @code{t} is the preferred way
to represent the truth value @var{true}.  When you need to choose a
value that represents @var{true}, and there is no other basis for
choosing, use @code{t}.  The symbol @code{t} always has the value
@code{t}.

  In Emacs Lisp, @code{nil} and @code{t} are special symbols that always
evaluate to themselves.  This is so that you do not need to quote them
to use them as constants in a program.  An attempt to change their
values results in a @code{setting-constant} error.  @xref{Constant
Variables}.

@defun booleanp object
Return non-@code{nil} if @var{object} is one of the two canonical
boolean values: @code{t} or @code{nil}.
@end defun

@node Evaluation Notation
@subsection Evaluation Notation
@cindex evaluation notation
@cindex documentation notation
@cindex notation

  A Lisp expression that you can evaluate is called a @dfn{form}.
Evaluating a form always produces a result, which is a Lisp object.  In
the examples in this manual, this is indicated with @samp{@result{}}:

@example
(car '(1 2))
     @result{} 1
@end example

@noindent
You can read this as ``@code{(car '(1 2))} evaluates to 1''.

  When a form is a macro call, it expands into a new form for Lisp to
evaluate.  We show the result of the expansion with
@samp{@expansion{}}.  We may or may not show the result of the
evaluation of the expanded form.

@example
(third '(a b c))
     @expansion{} (car (cdr (cdr '(a b c))))
     @result{} c
@end example

  To help describe one form, we sometimes show another form that
produces identical results.  The exact equivalence of two forms is
indicated with @samp{@equiv{}}.

@example
(make-sparse-keymap) @equiv{} (list 'keymap)
@end example

@node Printing Notation
@subsection Printing Notation
@cindex printing notation

  Many of the examples in this manual print text when they are
evaluated.  If you execute example code in a Lisp Interaction buffer
(such as the buffer @file{*scratch*}), the printed text is inserted into
the buffer.  If you execute the example by other means (such as by
evaluating the function @code{eval-region}), the printed text is
displayed in the echo area.

  Examples in this manual indicate printed text with @samp{@print{}},
irrespective of where that text goes.  The value returned by
evaluating the form follows on a separate line with
@samp{@result{}}.

@example
@group
(progn (prin1 'foo) (princ "\n") (prin1 'bar))
     @print{} foo
     @print{} bar
     @result{} bar
@end group
@end example

@node Error Messages
@subsection Error Messages
@cindex error message notation

  Some examples signal errors.  This normally displays an error message
in the echo area.  We show the error message on a line starting with
@samp{@error{}}.  Note that @samp{@error{}} itself does not appear in
the echo area.

@example
(+ 23 'x)
@error{} Wrong type argument: number-or-marker-p, x
@end example

@node Buffer Text Notation
@subsection Buffer Text Notation
@cindex buffer text notation

  Some examples describe modifications to the contents of a buffer, by
showing the before and after versions of the text.  These
examples show the contents of the buffer in question between two lines
of dashes containing the buffer name.  In addition, @samp{@point{}}
indicates the location of point.  (The symbol for point, of course, is
not part of the text in the buffer; it indicates the place
@emph{between} two characters where point is currently located.)

@example
---------- Buffer: foo ----------
This is the @point{}contents of foo.
---------- Buffer: foo ----------

(insert "changed ")
     @result{} nil
---------- Buffer: foo ----------
This is the changed @point{}contents of foo.
---------- Buffer: foo ----------
@end example

@node Format of Descriptions
@subsection Format of Descriptions
@cindex description format

  Functions, variables, macros, commands, user options, and special
forms are described in this manual in a uniform format.  The first
line of a description contains the name of the item followed by its
arguments, if any.
@ifnottex
The category---function, variable, or whatever---appears at the
beginning of the line.
@end ifnottex
@iftex
The category---function, variable, or whatever---is printed next to the
right margin.
@end iftex
The description follows on succeeding lines, sometimes with examples.

@menu
* A Sample Function Description::       A description of an imaginary
                                          function, @code{foo}.
* A Sample Variable Description::       A description of an imaginary
                                          variable,
                                          @code{electric-future-map}.
@end menu

@node A Sample Function Description
@subsubsection A Sample Function Description
@cindex function descriptions
@cindex command descriptions
@cindex macro descriptions
@cindex special form descriptions

  In a function description, the name of the function being described
appears first.  It is followed on the same line by a list of argument
names.  These names are also used in the body of the description, to
stand for the values of the arguments.

  The appearance of the keyword @code{&optional} in the argument list
indicates that the subsequent arguments may be omitted (omitted
arguments default to @code{nil}).  Do not write @code{&optional} when
you call the function.

  The keyword @code{&rest} (which must be followed by a single
argument name) indicates that any number of arguments can follow.  The
single argument name following @code{&rest} receives, as its
value, a list of all the remaining arguments passed to the function.
Do not write @code{&rest} when you call the function.

  Here is a description of an imaginary function @code{foo}:

@defun foo integer1 &optional integer2 &rest integers
The function @code{foo} subtracts @var{integer1} from @var{integer2},
then adds all the rest of the arguments to the result.  If @var{integer2}
is not supplied, then the number 19 is used by default.

@example
(foo 1 5 3 9)
     @result{} 16
(foo 5)
     @result{} 14
@end example

@need 1500
More generally,

@example
(foo @var{w} @var{x} @var{y}@dots{})
@equiv{}
(+ (- @var{x} @var{w}) @var{y}@dots{})
@end example
@end defun

  By convention, any argument whose name contains the name of a type
(e.g., @var{integer}, @var{integer1} or @var{buffer}) is expected to
be of that type.  A plural of a type (such as @var{buffers}) often
means a list of objects of that type.  An argument named @var{object}
may be of any type.  (For a list of Emacs object types, @pxref{Lisp
Data Types}.)  An argument with any other sort of name
(e.g., @var{new-file}) is specific to the function; if the function
has a documentation string, the type of the argument should be
described there (@pxref{Documentation}).

  @xref{Lambda Expressions}, for a more complete description of
arguments modified by @code{&optional} and @code{&rest}.

  Command, macro, and special form descriptions have the same format,
but the word @samp{Function} is replaced by @samp{Command},
@samp{Macro}, or @samp{Special Form}, respectively.  Commands are
simply functions that may be called interactively; macros process
their arguments differently from functions (the arguments are not
evaluated), but are presented the same way.

  The descriptions of macros and special forms use a more complex
notation to specify optional and repeated arguments, because they can
break the argument list down into separate arguments in more
complicated ways.  @samp{@r{[}@var{optional-arg}@r{]}} means that
@var{optional-arg} is optional and @samp{@var{repeated-args}@dots{}}
stands for zero or more arguments.  Parentheses are used when several
arguments are grouped into additional levels of list structure.  Here
is an example:

@defspec count-loop (var [from to [inc]]) body@dots{}
This imaginary special form implements a loop that executes the
@var{body} forms and then increments the variable @var{var} on each
iteration.  On the first iteration, the variable has the value
@var{from}; on subsequent iterations, it is incremented by one (or by
@var{inc} if that is given).  The loop exits before executing @var{body}
if @var{var} equals @var{to}.  Here is an example:

@example
(count-loop (i 0 10)
  (prin1 i) (princ " ")
  (prin1 (aref vector i))
  (terpri))
@end example

If @var{from} and @var{to} are omitted, @var{var} is bound to
@code{nil} before the loop begins, and the loop exits if @var{var} is
non-@code{nil} at the beginning of an iteration.  Here is an example:

@example
(count-loop (done)
  (if (pending)
      (fixit)
    (setq done t)))
@end example

In this special form, the arguments @var{from} and @var{to} are
optional, but must both be present or both absent.  If they are present,
@var{inc} may optionally be specified as well.  These arguments are
grouped with the argument @var{var} into a list, to distinguish them
from @var{body}, which includes all remaining elements of the form.
@end defspec

@node A Sample Variable Description
@subsubsection A Sample Variable Description
@cindex variable descriptions
@cindex option descriptions

  A @dfn{variable} is a name that can be @dfn{bound} (or @dfn{set}) to
an object.  The object to which a variable is bound is called a
@dfn{value}; we say also that variable holds that value.
Although nearly all variables can be set by the user, certain
variables exist specifically so that users can change them; these are
called @dfn{user options}.  Ordinary variables and user options are
described using a format like that for functions, except that there
are no arguments.

  Here is a description of the imaginary @code{electric-future-map}
variable.

@defvar electric-future-map
The value of this variable is a full keymap used by Electric Command
Future mode.  The functions in this map allow you to edit commands you
have not yet thought about executing.
@end defvar

  User option descriptions have the same format, but @samp{Variable}
is replaced by @samp{User Option}.

@node Version Info
@section Version Information

  These facilities provide information about which version of Emacs is
in use.

@deffn Command emacs-version &optional here
This function returns a string describing the version of Emacs that is
running.  It is useful to include this string in bug reports.

@smallexample
@group
(emacs-version)
  @result{} "GNU Emacs 24.5.1 (x86_64-unknown-linux-gnu, GTK+ Version 3.16)
             of 2015-06-01"
@end group
@end smallexample

If @var{here} is non-@code{nil}, it inserts the text in the buffer
before point, and returns @code{nil}.  When this function is called
interactively, it prints the same information in the echo area, but
giving a prefix argument makes @var{here} non-@code{nil}.
@end deffn

@defvar emacs-build-time
The value of this variable indicates the time at which Emacs was
built.  It is a list of four integers, like the value of
@code{current-time} (@pxref{Time of Day}).

@example
@group
emacs-build-time
     @result{} (20614 63694 515336 438000)
@end group
@end example
@end defvar

@defvar emacs-version
The value of this variable is the version of Emacs being run.  It is a
string such as @code{"23.1.1"}.  The last number in this string is not
really part of the Emacs release version number; it is incremented
each time Emacs is built in any given directory.  A value with four
numeric components, such as @code{"22.0.91.1"}, indicates an
unreleased test version.
@end defvar

@defvar emacs-major-version
The major version number of Emacs, as an integer.  For Emacs version
23.1, the value is 23.
@end defvar

@defvar emacs-minor-version
The minor version number of Emacs, as an integer.  For Emacs version
23.1, the value is 1.
@end defvar

@node Acknowledgments
@section Acknowledgments

  This manual was originally written by Robert Krawitz, Bil Lewis, Dan
LaLiberte, Richard@tie{}M. Stallman and Chris Welty, the volunteers of
the GNU manual group, in an effort extending over several years.
Robert@tie{}J. Chassell helped to review and edit the manual, with the
support of the Defense Advanced Research Projects Agency, ARPA Order
6082, arranged by Warren@tie{}A. Hunt, Jr.@: of Computational Logic,
Inc.  Additional sections have since been written by Miles Bader, Lars
Brinkhoff, Chong Yidong, Kenichi Handa, Lute Kamstra, Juri Linkov,
Glenn Morris, Thien-Thi Nguyen, Dan Nicolaescu, Martin Rudalics, Kim
F. Storm, Luc Teirlinck, and Eli Zaretskii, and others.

  Corrections were supplied by Drew Adams, Juanma Barranquero, Karl
Berry, Jim Blandy, Bard Bloom, Stephane Boucher, David Boyes, Alan
Carroll, Richard Davis, Lawrence R. Dodd, Peter Doornbosch, David
A. Duff, Chris Eich, Beverly Erlebacher, David Eckelkamp, Ralf Fassel,
Eirik Fuller, Stephen Gildea, Bob Glickstein, Eric Hanchrow, Jesper
Harder, George Hartzell, Nathan Hess, Masayuki Ida, Dan Jacobson, Jak
Kirman, Bob Knighten, Frederick M. Korz, Joe Lammens, Glenn M. Lewis,
K. Richard Magill, Brian Marick, Roland McGrath, Stefan Monnier, Skip
Montanaro, John Gardiner Myers, Thomas A. Peterson, Francesco Potortì,
Friedrich Pukelsheim, Arnold D. Robbins, Raul Rockwell, Jason Rumney,
Per Starbäck, Shinichirou Sugou, Kimmo Suominen, Edward Tharp, Bill
Trost, Rickard Westman, Jean White, Eduard Wiebe, Matthew Wilding,
Carl Witty, Dale Worley, Rusty Wright, and David D. Zuhn.

  For a more complete list of contributors, please see the relevant
change log entries in the Emacs source repository.
